Transport behavior of groundwater protozoa and protozoan-sized microspheres in sandy aquifer sediments

Harvey, Ronald W.; Kinner, Nancy E.; Bunn, Amoret L.; Macdonald, D.M.; Metge, David W.

doi:10.1128/aem.61.1.209-217.1995

Cited by 101 publications

(69 citation statements)

References 28 publications

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“…Extended tailing may occur during the elution phase of unfavorable experiments (Figure 2, left and middle top row). Tailing is defined by the slow release of colloids from the column (illustrated in Figure 2) and is indicative of significant reentrainment, as observed for microbes in the laboratory [Fontes et al, 1991;Hornberger et al, 1992;Lindqvist et al, 1994;McCaulou et al, 1994;Johnson et al, 1995b;McCaulou et al, 1995;Hendry et al, 1997Hendry et al, , 1999Harter et al, 2000;, field [Scholl and Harvey, 1992;Harvey et al, 1995;DeBorde et al, 1999;Ryan et al, 1999;Schijven et al, 1999], and nonbiological colloids [Li et al, 2004;Tufenkji et al, 2004;Tong et al, 2005;Johnson et al, 2007b]. The reentrainment behavior under unfavorable conditions is sensitive to solution chemistry and fluid flow as shown for reentrainment with perturbations, including variation in ionic strength [Ryan et al, 1999;Tufenkji andElimelech, 2004a, 2005a;Shen et al, 2007;Mattison et al, 2011;Jiang et al, 2012a;Shen et al, 2012], variation in pH [Ryan et al, 1999;Tufenkji andElimelech, 2004a, 2005a], and variation in fluid velocity [Shang et al, 2008;Pazmino et al, 2014a].…”

Section: 1002/2015wr017318mentioning

confidence: 99%

“…As such, slight differences in colloid size and/or surface properties may generate effective heterogeneity in ''stickiness'' among the colloid population. Demonstrating this effect may yield a mechanistic explanation for the apparent heterogeneity in retention rate coefficients among apparently uniform populations, which is thought to drive the observed nonlog linear profiles of retained colloids observed under unfavorable conditions [Albinger et al, 1994;Harvey et al, 1995;Hendry et al, 1997;Baygents et al, 1998;Simoni et al, 1998;Bolster et al, 1999;Schijven et al, 1999;Bolster et al, 2000;Li et al, 2004;Tufenkji and Elimelech, 2004a;Tufenkji et al, 2004;Tufenkji and Elimelech, 2005a,b;Tong and Johnson, 2007;Liang et al, 2013;D. Wang et al, 2014].…”

Section: 1002/2015wr017318mentioning

confidence: 99%

“…Colloid transport from septic systems, agricultural runoff, and other sources through near-shore soils may lead to elevated concentrations of pathogenic colloids in beach sands [e.g., Lipp et al, 2001] and transport across the groundwater/ surface water interface may be the cause of frequent beach closures [e.g., Russell et al, 2012]. A wide array of research into pathogen transport has been undertaken including virus transport [Ryan et al, 1999;Schijven et al, 1999;Jin and Flury, 2002] and column-scale bacteria transport [e.g., Albinger et al, 1994;Baygents et al, 1998;Simoni et al, 1998;Torkzaban et al, 2008], bacteria transport in the field [Bales et al, 1989;Powelson et al, 1993;Harvey et al, 1995;DeBorde et al, 1999;Ryan et al, 1999;Schijven et al, 1999;Zhang et al, 2001a;Ryan et al, 2002;Blanford et al, 2005;van der Wielen et al, 2008;Scheibe et al, 2011], and phage persistence in soils [e.g., Yates et al, 1985] among many others; numerous reviews of pathogen transport in groundwater are available [Bitton and Harvey, 1992;Harvey, 1997;Taylor et al, 2004;Sen, 2011].…”

Section: Introductionmentioning

confidence: 99%

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Predicting colloid transport through saturated porous media: A critical review

et al. 2015

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Understanding and predicting colloid transport and retention in water‐saturated porous media is important for the protection of human and ecological health. Early applications of colloid transport research before the 1990s included the removal of pathogens in granular drinking water filters. Since then, interest has expanded significantly to include such areas as source zone protection of drinking water systems and injection of nanometals for contaminated site remediation. This review summarizes predictive tools for colloid transport from the pore to field scales. First, we review experimental breakthrough and retention of colloids under favorable and unfavorable colloid/collector interactions (i.e., no significant and significant colloid‐surface repulsion, respectively). Second, we review the continuum‐scale modeling strategies used to describe observed transport behavior. Third, we review the following two components of colloid filtration theory: (i) mechanistic force/torque balance models of pore‐scale colloid trajectories and (ii) approximating correlation equations used to predict colloid retention. The successes and limitations of these approaches for favorable conditions are summarized, as are recent developments to predict colloid retention under the unfavorable conditions particularly relevant to environmental applications. Fourth, we summarize the influences of physical and chemical heterogeneities on colloid transport and avenues for their prediction. Fifth, we review the upscaling of mechanistic model results to rate constants for use in continuum models of colloid behavior at the column and field scales. Overall, this paper clarifies the foundation for existing knowledge of colloid transport and retention, features recent advances in the field, critically assesses where existing approaches are successful and the limits of their application, and highlights outstanding challenges and future research opportunities. These challenges and opportunities include improving mechanistic descriptions, and subsequent correlation equations, for nanoparticle (i.e., Brownian particle) transport through soil, developing mechanistic descriptions of colloid retention in so‐called “unfavorable” conditions via methods such as the “discrete heterogeneity” approach, and employing imaging techniques such as X‐ray tomography to develop realistic expressions for grain topology and mineral distribution that can aid the development of these mechanistic approaches.

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Section: 1002/2015wr017318mentioning

confidence: 99%

Section: 1002/2015wr017318mentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

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Predicting colloid transport through saturated porous media: A critical review

et al. 2015

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“…There are several classes of colloids, biotic and abiotic. Among biotic colloids, significant attention has been given to viruses [Burge and Enkiri, 1978;Pieper et al, 1997;Bales et al, 1997;Woessner et al, 2001], bacteria [Edniond, 1976;Harvey et al, 1989] and protozoa [Sinclair and Ghiorse, 1987;Harvey et al, 1995;Harter et al, 2000]. The motivation comes from a growing concern about potential health problems from contaminated drinking water aquifers [Hejkal et al, 1982] and bioremediation strategies that introduce exogenous bacteria strains [Straube et al, 2003].…”

Section: Introductionmentioning

confidence: 99%

Pore‐scale processes that control dispersion of colloids in saturated porous media

Auset

Keller

2004

Water Resources Research

166

130

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[1] Colloidal dispersion in porous media is a consequence of the different paths and velocities experienced by the colloids. We examined at the pore scale the effect of particle and pore size on colloid dispersion using water-saturated micromodels. The micromodels were produced with polydimethylsiloxane (PDMS), using a soft photolithography technique that allows creating transparent patterns that have dimensions in the range of those existing at the pore space. Four sizes of colloids were transported at several total pressure differences, and image analysis was used to determine particle trajectories, residence times, and dispersion coefficients through the micromodels. The magnitude of the dispersion at any given flow rate was found to be controlled by the pore-space geometry and the relative size of colloids with regards to pore channels. Dispersion coefficient and dispersivity decrease with increasing colloid size. Dispersivity is thus not just a function of pore geometry but depends on colloid characteristics. Because of their size, larger colloids travel in the center streamlines, leading to faster velocities, less detours, and thus lower range of transit times. These findings emphasize the role of particle and pore size on colloidal dispersion and have significant implications for predicting the movement of colloids through saturated porous media.

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“…A vast accumulation of literature in the fields of soil science, geosciences, and petroleum engineering has provided overwhelming evidence that solute transport in undisturbed subsurface media is often influenced by preferential flow coupled with matrix diffusion [Shuford et al, 1977;Shaffer et al, 1979;Frohne and Mercer, 1984;Abelin et al, 1987Abelin et al, , 1991Seyfried and Rao, 1987;Jardine et al, 1988Jardine et al, , 1990Jardine et al, , 1993a with grossly different sizes. At the field scale, techniques 4 and 5 are most practical for quantifying advective preferential flow and time-dependent diffusion into the soil and bedrock matrix [Abelin et al, 1987;Harvey et al, 1989Harvey et al, , 1993Harvey et al, , 1995Raven et al, 1988;Zuber, 1990, 1993;McKay et al, 1993aMcKay et al, , b, 1995Sanford and Solomon, 1998;Jaynes and Horton, 1998]. The use of multiple tracers with different diffusion coefficients is particularly useful because the influence of matrix diffusion on the overall system dispersion can be quantified.…”

Section: Introductionmentioning

confidence: 99%

Quantifying diffusive mass transfer in fractured shale bedrock

Jardine¹,

Sanford²,

Gwo³

et al. 1999

Water Resources Research

116

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A significant limitation in defining remediation needs at contaminated sites often results from an insufficient understanding of the transport processes that control contaminant migration. The objectives of this research were to help resolve this dilemma by providing an improved understanding of contaminant transport processes in highly structured, heterogeneous subsurface environments that are complicated by fracture flow and matrix diffusion. Our approach involved a unique long‐term, steady state natural gradient injection of multiple tracers with different diffusion coefficients (Br, He, Ne) into a fracture zone of a contaminated shale bedrock. The spatial and temporal distribution of the tracers was monitored for 550 days using an array of groundwater sampling wells instrumented within a fast flowing fracture regime and a slow flowing matrix regime. The tracers were transported preferentially along strike‐parallel fractures, with a significant portion of the tracer plumes migrating slowly into the bedrock matrix. Movement into the matrix was controlled by concentration gradients established between preferential flow paths and the adjacent rock matrix. Observed differences in tracer mobility into the matrix were found to be a function of their free‐water molecular diffusion coefficients. The multiple tracer technique confirmed that matrix diffusion was a significant process that contributed to the overall physical nonequilibrium that controlled contaminant transport in the shale bedrock. The experimental observations were consistent with numerical simulations of the multitracer breakthrough curves using a simple fracture flow model. The simulated results also demonstrated the significance of contaminant diffusion into the bedrock matrix. The multiple tracer technique and ability to monitor the fracture and matrix regimes provided the necessary experimental constraints for the accurate numerical quantification of the diffusive mass transfer process. The experimental and numerical results of the tracer study were also consistent with indigenous contaminant discharge concentrations within the fracture and matrix regimes of the field site. These findings suggest that the secondary source contribution of the bedrock matrix to the total off‐site transport of contaminants is relatively large and potentially long‐lived.

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Transport behavior of groundwater protozoa and protozoan-sized microspheres in sandy aquifer sediments

Cited by 101 publications

References 28 publications

Predicting colloid transport through saturated porous media: A critical review

Predicting colloid transport through saturated porous media: A critical review

Pore‐scale processes that control dispersion of colloids in saturated porous media

Quantifying diffusive mass transfer in fractured shale bedrock

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