Transport of <i>E. coli</i> in aquifer sediments of Bangladesh: Implications for widespread microbial contamination of groundwater

Feighery, John; Mailloux, Brian J.; Ferguson, A.; Ahmed, Kazi Matin; Geen, Alexander van; Culligan, Patricia J.

doi:10.1002/wrcr.20289

Cited by 19 publications

(16 citation statements)

References 56 publications

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“…Model fits were good with R 2 values ranging from 0.97 to 0.99. The dispersivity value calculated by CXTFIT 2.1 was approximately 0.289 cm, which is typical for these types of experiments, and is consistent with the range of values (0.06 to 0.816 cm) reported by others [38][39][40][41][42][43]. Next, the hydraulics of the HYDRUS model domain was calibrated using the conservative tracer breakthrough curves (BTC).…”

Section: Resultssupporting

confidence: 83%

Transport of Pathogen Surrogates in Soil Treatment Units: Numerical Modeling

Morales

Atoyan

Amador

et al. 2014

Water

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Abstract:Segmented mesocosms (n = 3) packed with sand, sandy loam or clay loam soil were used to determine the effect of soil texture and depth on transport of two septic tank effluent (STE)-borne microbial pathogen surrogates-green fluorescent protein-labeled E. coli (GFPE) and MS-2 coliphage-in soil treatment units. HYDRUS 2D/3D software was used to model the transport of these microbes from the infiltrative surface. Mesocosms were spiked with GFPE and MS-2 coliphage at 10 5 cfu/mL STE and 10 5 -10 6 pfu/mL STE, respectively. In all soils, removal rates were >99.99% at 25 cm. The transport simulation compared (1) optimization; and (2) trial-and-error modeling approaches. Only slight differences between the transport parameters were observed between these approaches. Treating both the die-off rates and attachment/detachment rates as variables resulted in an overall better model fit, particularly for the tailing phase of the experiments. Independent of the fitting procedure, attachment rates computed by the model were higher in sandy and sandy loam soils than clay, which was attributed to unsaturated flow conditions at lower water content in the coarser-textured soils. Early breakthrough of the bacteria and virus indicated the presence of preferential flow in the system in the structured clay loam soil, resulting in faster movement of water and microbes through the soil relative to a conservative tracer (bromide).

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Section: Resultssupporting

confidence: 83%

Transport of Pathogen Surrogates in Soil Treatment Units: Numerical Modeling

Morales

Atoyan

Amador

et al. 2014

Water

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“…Understanding of the attachment-detachment kinetics has important implication in risk assessment. Detachment is considered a major reason for the widespread microbial contamination of some shallow groundwater and allows microbial contaminants to move much further into an aquifer (Feighery et al, 2013;Knappett et al, 2014). A constantly slow release of viruses from previously attached in the porous media will lengthen the contamination duration, and a sudden release of microbial contaminants due to a change of hydraulic conditions (e.g.…”

Section: Limitations and Implicationsmentioning

confidence: 99%

Mimicking filtration and transport of rotavirus and adenovirus in sand media using DNA-labeled, protein-coated silica nanoparticles

et al. 2014

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“…The elevated Eh nano-redox conditions (> 0.7 V) within the ZVI intraparticle porosity are suitable for the growth of Escherichia coli, Listeria monocytogenes, Pseudomonas aeruginosa and Staphylococcus aureus (e.g., Deza et al 2005). These species are natural constituents of many shallow aquifers (e.g., Ridgway et al 1990;Hossain and Anwar 2009;Feighery et al 2013;Penny et al 2015). The sheltered intra-particle nano-environment will, in some aquifers, result in colonies of these species growing within the ZVI during desalination.…”

Section: Secondary Reactionsmentioning

confidence: 99%

ZVI (Fe0) desalination: catalytic partial desalination of saline aquifers

Antia¹

2018

Appl Water Sci

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Globally, salinization affects between 100 and 1000 billion m 3 a −1 of irrigation water. The discovery that zero valent iron (ZVI, Fe 0 ) could be used to desalinate water (using intra-particle catalysis in a diffusion environment) raises the possibility that large-scale in situ desalination of aquifers could be undertaken to support agriculture. ZVI desalination removes NaCl by an adsorption-desorption process in a multi-stage cross-coupled catalytic process. This study considers the potential application of two ZVI desalination catalyst types for in situ aquifer desalination. The feasibility of using ZVI catalysts when placed in situ within an aquifer to produce 100 m 3 d −1 of partially desalinated water from a saline aquifer is considered.

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Transport of E. coli in aquifer sediments of Bangladesh: Implications for widespread microbial contamination of groundwater

Cited by 19 publications

References 56 publications

Transport of Pathogen Surrogates in Soil Treatment Units: Numerical Modeling

Transport of Pathogen Surrogates in Soil Treatment Units: Numerical Modeling

Mimicking filtration and transport of rotavirus and adenovirus in sand media using DNA-labeled, protein-coated silica nanoparticles

ZVI (Fe0) desalination: catalytic partial desalination of saline aquifers

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