Does Colloid Shape Affect Detachment of Colloids by a Moving Air–Water Interface?

Aramrak, Surachet; Flury, Markus; Harsh, James B.; Zollars, Richard L.; Davis, Howard

doi:10.1021/la400252q

Cited by 51 publications

(38 citation statements)

References 43 publications

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“…A comparable situation has been studied, and the effect verified, with ellipsoidal polystyrene colloidal particles in Ref. [24], though with a much smaller aspect ratio than with MWNTs. The orientation effect is also in accordance with our previous study [9].…”

Section: The Surface Tension Force At the Contact Linementioning

confidence: 59%

On-chip purification via liquid immersion of arc-discharge synthesized multiwalled carbon nanotubes

et al. 2016

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Section: The Surface Tension Force At the Contact Linementioning

confidence: 59%

On-chip purification via liquid immersion of arc-discharge synthesized multiwalled carbon nanotubes

et al. 2016

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“…5a. The differences of the structural disruptions to the DPPC monolayer by NPs of various shapes together with their trans-membrane dynamics can be ascribed to two points: (1) Particle shape influences the capillary forces acting on particles at the air-water interface, which is important for NP dynamics [23,24]. (2) Particle shape affects the rotation and orientation abilities of NPs on the membrane [25,26,29].…”

Section: Discussionmentioning

confidence: 99%

Shape affects the interactions of nanoparticles with pulmonary surfactant

Lin

Zuo

2015

Sci. China Mater.

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The interactions with the pulmonary surfactant, the initial biological barrier of respiratory pathway, determine the potential therapeutic applications and toxicological effects of inhaled nanoparticles (NPs). Although much attention has been paid to optimize the physicochemical properties of NPs for improved delivery and targeting, shape effects of the inhaled NPs on their interactions with the pulmonary surfactant are still far from clear. Here, we studied the shape effects of NPs on their penetration abilities and structural disruptions to the dipalmitoyl-phosphatidylcholine (DPPC) monolayer (being model pulmonary surfactant film) using coarse-grained molecular dynamics simulations. It is found that during the inspiration process (i.e., surfactant film expansion), shape effects are negligible. However, during the expiration process (i.e., surfactant film compression), NPs of different shapes show various penetration abilities and degrees of structural disruptions to the DPPC monolayer. We found that rod-like NPs showed the highest degree of penetration and the smallest side-effects to the DPPC monolayer. Our results may provide a useful insight into the design of NPs for respiratory therapeutics.

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“…We showed that intermittent rainfall can mobilize microspheres, and the mobilization could be particularly high in soil with greater permeability because of the presence of macropores. However, the transport and mobilization of actual pathogens can vary from that of microspheres (Harvey et al, 1989), possibly due to differences in contact points (Harvey et al, 2011), shape (Aramrak et al, 2013), density (Zvikelsky et al, 2008), and surface properties (Weisbrod et al, 2013). Furthermore, pathogens could lose their virulence and, perhaps, their viability during desiccation; both factors could either decrease or increase the mobilization of viable, infectious pathogens.…”

Section: Discussionmentioning

confidence: 99%

Mobilization of Microspheres from a Fractured Soil during Intermittent Infiltration Events

Mohanty

Bulicek

Metge

et al. 2015

Vadose Zone Journal

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The vadose zone filters pathogenic microbes from infiltrating water and consequently protects the groundwater from possible contamination. In some cases, however, the deposited microbes may be mobilized during rainfall and migrate into the groundwater. We examined the mobilization of microspheres, surrogates for microbes, in an intact core of a fractured soil by intermittent simulated rainfall. Fluorescent polystyrene microspheres of two sizes (0.5 and 1.8 mm) and Br− were first applied to the core to deposit the microspheres, and then the core was subjected to three intermittent infiltration events to mobilize the deposited microspheres. Collecting effluent samples through a 19‐port sampler at the base of the core, we found that water flowed through only five ports, and the flow rates varied among the ports by a factor of 12. These results suggest that flow paths leading to the ports had different permeabilities, partly due to macropores. Although 40 to 69% of injected microspheres were retained in the core during their application, 12 to 30% of the retained microspheres were mobilized during three intermittent infiltration events. The extent of microsphere mobilization was greater in flow paths with greater permeability, which indicates that macropores could enhance colloid mobilization during intermittent infiltration events. In all ports, the 1.8‐mm microspheres were mobilized to a greater extent than the 0.5‐mm microspheres, suggesting that larger colloids are more likely to mobilize. These results are useful in assessing the potential of pathogen mobilization and colloid‐facilitated transport of contaminants in the subsurface under natural infiltration events.

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Does Colloid Shape Affect Detachment of Colloids by a Moving Air–Water Interface?

Cited by 51 publications

References 43 publications

On-chip purification via liquid immersion of arc-discharge synthesized multiwalled carbon nanotubes

On-chip purification via liquid immersion of arc-discharge synthesized multiwalled carbon nanotubes

Shape affects the interactions of nanoparticles with pulmonary surfactant

Mobilization of Microspheres from a Fractured Soil during Intermittent Infiltration Events

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