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Disruption of polystyrene latex aggregates in capillary flow
S. Tang
*
, C. M. McFarlane,
Z. Zhang
*
Corresponding author for this work
Chemical Engineering
Research output
:
Contribution to journal
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Article
›
peer-review
3
Citations (Scopus)
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Keyphrases
Capillary Flow
100%
Polystyrene Latex Particles
100%
Colloidal Aggregation
100%
Diffusion Limit
55%
Reaction Limit
44%
Aggregate Size
22%
Steady State
11%
Electrolyte
11%
Stirrer
11%
Shear Rate
11%
Turbulent Flow
11%
Latex Particles
11%
Sampling Methods
11%
Acid Phosphate
11%
Phosphate-buffered Saline
11%
Fractal Dimension
11%
Reduction Degree
11%
Mean Diameter
11%
High Shear Rate
11%
Citric Acid
11%
Aggregate Disruption
11%
Small Angle
11%
Deuterium Oxide
11%
Sampling Unit
11%
Fractal Nature
11%
Capillary Tube
11%
Laser Scattering
11%
Aggregate Volume
11%
Deuterium Water
11%
Material Science
Polystyrene
100%
Density
50%
Oxide Compound
50%
Deuterium
50%
Buffer Solution
50%
Turbulent Flow
50%
Laser Scattering
50%
Pharmacology, Toxicology and Pharmaceutical Science
Styrofoam
100%
Buffer
50%
Elimination
50%
Latex
50%
Deuterium Oxide
50%
Engineering
Disruptions
100%
Colloid
100%
Turbulent Flow
11%
Shear Rate
11%
Latex
11%
High Shear Rate
11%
Fractal Dimension
11%
Size Dimension
11%
Capillary Tube
11%
Heavy Water
11%
Acid Phosphate
11%