Comparison of Types and Amounts of Nanoscale Heterogeneity on Bacteria Retention

Bradford, Scott A.; Sasidharan, Salini; Kim, Hyun-Jung; Hwang, Gukhwa

doi:10.3389/fenvs.2018.00056

Cited by 35 publications

(23 citation statements)

References 76 publications

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“…Furthermore, differences in AgNP retention on QW and GF sands are not predicted because values of F max were nearly identical (39.4 and 40.1 for QW and GF sand, respectively). Potential explanations for these discrepancies include nanoscale charge heterogeneity and roughness which can locally reduce and/or eliminate the energy barrier (Suresh and Walz, 1996;Bhattacharjee et al, 1998;Hoek et al, 2003;Hoek and Agarwal, 2006;Bradford et al, 2017;Bradford et al, 2018). Nanoscale chemical heterogeneity that is larger than a critical size can create regions on a net unfavorable surface that are favorable for interaction between the colloid and the solid surface due to a local reduction in the energy barrier and an increase in the depth of the primary minimum.…”

Section: Agnp Retention In the Sand With A Rough Surfacementioning

confidence: 99%

Evidence for the critical role of nanoscale surface roughness on the retention and release of silver nanoparticles in porous media

Liang

Zhou

Dong

et al. 2020

Environmental Pollution

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Although nanoscale surface roughness has been theoretically demonstrated to be a crucial factor in the interaction of colloids and surfaces, little experimental research has investigated the influence of roughness on colloid or silver nanoparticle (AgNP) retention and release in porous media. This study experimentally examined AgNP retention and release using two sands with very different surface roughness properties over a range of solution pH and/or ionic strength (IS). AgNP transport was greatly enhanced on the relatively smooth sand in comparison to the rougher sand, at higher pH, and lower IS and fitted model parameters showed systematic changes with these physicochemical factors. Complete release of the retained AgNPs was observed from the relatively smooth sand when the solution IS was decreased from 40 mM NaCl to deionized (DI) water and then the solution pH was increased from 6.5 to 10. Conversely, less than 40% of the retained AgNPs was released in similar processes from the rougher sand. These observations were explained by differences in the surface roughness of the two sands which altered the energy barrier height and the depth of the primary minimum with solution chemistry. Limited numbers of AgNPs apparently interacted in reversible, shallow primary minima on the smoother sand, which is consistent with the predicted influence of a small roughness fraction (e.g., pillar) on interaction energies. Conversely, larger numbers of AgNPs interacted in deeper primary minima on the rougher sand, which is consistent with the predicted influence at concave locations. These findings highlight the importance of surface roughness and indicate that variations in sand surface roughness can greatly change the sensitivity of nanoparticle transport to physicochemical factors such as IS and pH due to the alteration of interaction energy and thus can strongly influence nanoparticle mobility in the environment.

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Section: Agnp Retention In the Sand With A Rough Surfacementioning

confidence: 99%

Evidence for the critical role of nanoscale surface roughness on the retention and release of silver nanoparticles in porous media

Liang

Zhou

Dong

et al. 2020

Environmental Pollution

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“…SOM has been found to mask charge heterogeneities and cation bridging with clay particles (Cabal et al, 2010;Han et al, 2008). The interaction of SOM with AgNPs is also expected to be sensitive to the roughness density and height of the AgNP capping agent (Bradford et al, 2017(Bradford et al, , 2018 and the bonding energy between the capping agent and the AgNP (Gunsolus et al, 2015). Additional research is warranted to determine the underlying cause for differences in SOM-AgNP interactions, but a systematic evaluation of these factors is beyond the scope of this work.…”

Section: Agnpmentioning

confidence: 99%

“…However, no research has systematically examined the influence of calcite with impurities from silicate minerals and/or SOM coatings on AgNP transport. Chemical heterogeneities (CH) in such media will produce variations in charge, Hamaker constant (Bradford et al, 2018), and/or hydrophobicity (Tschapek, 1984).…”

Section: Introductionmentioning

confidence: 99%

“…The collector surface roughness has been found to play an important role in controlling the mobility and fate of nanoparticles due to its strong influence on interaction energies, hydrodynamic forces, and lever arms associated with hydrodynamic and adhesive torques (Morales et al, 2009;Torkzaban et al, 2010). When small amounts of NR occur on both porous medium and colloid surfaces the magnitudes of the secondary and primary minima, and the energy barriers are all strongly reduced in comparison to a smooth surface (Bendersky and Davis, 2011;Bhattacharjee et al, 1998;Bradford et al, 2018;Bradford and Torkzaban, 2013;Hoek and Agarwal, 2006), and the colloid may be susceptible to diffusive and/or hydrodynamic removal (Bradford and Torkzaban, 2015;Rasmuson et al, 2017). These changes in the interaction energy profile may even occur in the presence of CH, such that electrostatically favorable locations are unfavorable for colloid retention (Zhang et al, 2016).…”

Section: Introductionmentioning

confidence: 99%

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Transport and retention of engineered silver nanoparticles in carbonate-rich sediments in the presence and absence of soil organic matter

Adrian

Schneidewind

Bradford

et al. 2019

Environmental Pollution

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The transport and retention behavior of polymer-(PVP-AgNP) and surfactant-stabilized (AgPURE) silver nanoparticles in carbonate-dominated saturated and unconsolidated porous media was studied at the laboratory scale. Initial column experiments were conducted to investigate the influence of chemical heterogeneity (CH) and nano-scale surface roughness (NR) arising from mixtures of clean, positively charged calcium carbonate sand (CCS), and negatively charged quartz sands. Additional column experiments were performed to elucidate the impact of CH and NR arising from the presence and absence of soil organic matter (SOM) on a natural carbonate-dominated aquifer material. The role of the nanoparticle capping agent was examined under all conditions tested in the column experiments. Nanoparticle transport was well described using a numerical model that facilitated blocking on one or two retention sites. Results demonstrate that an increase in CCS content in the artificially mixed porous medium leads to delayed breakthrough of the AgNPs, although AgPURE was much less affected by the CCS content than PVP-AgNPs. Interestingly, only a small portion of the solid surface area contributed to AgNP retention, even on positively charged CCS, due to the presence of NR which weakened the adhesive interaction. The presence of SOM enhanced the retention of AgPURE on the natural carbonate-dominated aquifer material, which can be a result of hydrophobic or hydrophilic interactions or due to cation bridging. Surprisingly, SOM had no significant impact on PVP-AgNP retention, which suggests that a reduction in electrostatic repulsion due to the presence of SOM outweighs the relative importance of other binding mechanisms. Our findings are important for future studies related to AgNP transport in shallow unconsolidated calcareous and siliceous sands.

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“…It has been shown that the intrinsic surface properties of different types of plastics affect both long and short term bacterial adhesion to their surfaces (Cai et al, 2019). Variations in roughness on a nanoscale and surface chemical heterogeneity further confound assessment of bacterial adhesion onto fomites (Bradford et al, 2018).…”

Section: Fomite Features Influencing Microbial Adhesionmentioning

confidence: 99%

A Sticking Point in Assessing Bacterial Contamination: Adhesive Characters of Bacterial Specializations, Swab Features, and Fomite Surface Properties Skew Colony Counts

Motz¹,

Young²,

Motz³

et al. 2019

J Pure Appl Microbiol

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Comparison of Types and Amounts of Nanoscale Heterogeneity on Bacteria Retention

Cited by 35 publications

References 76 publications

Evidence for the critical role of nanoscale surface roughness on the retention and release of silver nanoparticles in porous media

Evidence for the critical role of nanoscale surface roughness on the retention and release of silver nanoparticles in porous media

Transport and retention of engineered silver nanoparticles in carbonate-rich sediments in the presence and absence of soil organic matter

A Sticking Point in Assessing Bacterial Contamination: Adhesive Characters of Bacterial Specializations, Swab Features, and Fomite Surface Properties Skew Colony Counts

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