Release of Colloids from Primary Minimum Contact under Unfavorable Conditions by Perturbations in Ionic Strength and Flow Rate

Colloid release from surfaces in response to ionic strength and flow perturbations has been mechanistically simulated. However, these models do not address the mechanism by which colloid attachment occurs, at least in the presence of bulk colloid–collector repulsion (unfavorable conditions), which i...

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Bibliographic Details
Published in:Environmental science & technology 2014-08, Vol.48 (16), p.9227-9235
Main Authors: Pazmino, Eddy, Trauscht, Jacob, Johnson, William P
Format: Article
Language:English
Subjects:
Colloids
Flow velocity
Fluid dynamics
Ions
Models, Theoretical
Osmolar Concentration
Simulation
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Summary:Colloid release from surfaces in response to ionic strength and flow perturbations has been mechanistically simulated. However, these models do not address the mechanism by which colloid attachment occurs, at least in the presence of bulk colloid–collector repulsion (unfavorable conditions), which is a prevalent environmental condition. We test whether a mechanistic model that predicts colloid attachment under unfavorable conditions also predicts colloid release in response to reduced ionic strength (IS) and increased fluid velocity (conditions thought prevalent for mobilization of environmental colloids). The model trades in mean-field colloid–collector interaction for discrete representation of surface heterogeneity, which accounts for a combination of attractive and repulsive interactions simultaneously, and results in an attached colloid population (in primary minimum contact with the surface) having a distribution of strengths of attraction. The model moderates equilibrium separation distance by inclusion of steric interactions. By using the same model parameters to quantitatively predict attachment under unfavorable conditions, simulated release of colloids (for all three sizes) from primary minimum attachment in response to perturbations qualitatively matched experimental results, demonstrating that both attachment and detachment were mechanistically simulated.
ISSN:0013-936X
1520-5851
DOI:10.1021/es502503y