Pore-Scale Study of Flow Rate on Colloid Attachment and Remobilization in a Saturated Micromodel.

@article{Zhang2015PoreScaleSO,
  title={Pore-Scale Study of Flow Rate on Colloid Attachment and Remobilization in a Saturated Micromodel.},
  author={Qiulan Zhang and Amir Raoof and S. Majid Hassanizadeh},
  journal={Journal of environmental quality},
  year={2015},
  volume={44 5},
  pages={
          1376-83
        }
}
Colloid attachment is an important retention mechanism. It is influenced by colloid size, pore size, and flow rate, among other factors. In this work, we studied colloid attachment experimentally under various flow rates, as well as colloid release in response to a rapid change of flow rate. Colloid transport experiments under saturated conditions and with different flow rates were conducted in a physical micromodel. The micromodel was made of polydimethylsiloxane (PDMS), which is a hydrophobic… 
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19 Citations

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References

SHOWING 1-10 OF 57 REFERENCES
Effects of solution chemistry on straining of colloids in porous media under unfavorable conditions
[1] This study examines effects of solution chemistry on straining of colloids in porous media under unfavorable conditions via theoretical analysis and laboratory column experiments. Geometric
Study of colloids transport during two-phase flow using a novel polydimethylsiloxane micro-model.
Hysteresis of colloid retention and release in saturated porous media during transients in solution chemistry.
TLDR
Upon stepwise reduction in eluting solution ionic strength (IS), a sharp release of colloids occurred in each step which indicates that colloid retention depends on a balance of applied (hydrodynamic) and resisting (adhesive) torques which varied with pore space geometry, surface roughness, and interaction energy.
Colloid Transport and Retention in Unsaturated Porous Media: A Review of Interface-, Collector-, and Pore-Scale Processes and Models
Our ability to accurately simulate the transport and retention of colloids in the vadose zone is currently limited by our lack of basic understanding of colloid retention processes that occur at the
Coupling of physical and chemical mechanisms of colloid straining in saturated porous media.
Modeling the coupled effects of pore space geometry and velocity on colloid transport and retention
TLDR
A dual-permeability model formulation is highlighted that can be used to account for enhanced colloid retention in low-velocity regions of the pore space and provided a good description of measured colloid breakthrough curves and retention profiles that were collected for a variety of conditions.
Modeling colloid attachment, straining, and exclusion in saturated porous media.
TLDR
Numerical experiments indicated that increasing the colloid excluded volume of the pore space resulted in earlier breakthrough and higher peak effluent concentrations as a result of higher pore water velocities and lower residence times, respectively.
Effects of Flow Velocity and Nonionic Surfactant on Colloid Straining in Saturated Porous Media Under Unfavorable Conditions
Knowledge of colloid straining mechanism in porous media is of importance for protecting groundwater from being contaminated by biocolloids (e.g., bacteria and protozoa) and by contaminants whose
Concentration dependent transport of colloids in saturated porous media.
Modeling colloid transport and retention in saturated porous media under unfavorable attachment conditions: MODELING COLLOID TRANSPORT AND RETENTION
[1] A mathematical model is presented for colloid transport and retention in saturated porous media under unfavorable attachment conditions. The model accounts for colloid transport in the bulk
...
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