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Hydrodynamically induced helical particle drift due to patterned surfaces
Danielle L. Chase
, Christina Kurzthaler
,
Howard A. Stone
Mechanical & Aerospace Engineering
Chemical & Biological Engineering
High Meadows Environmental Institute
Lewis-Sigler Institute for Integrative Genomics
Molecular Biology
Princeton Materials Institute
Research output
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Contribution to journal
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Article
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peer-review
13
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Keyphrases
Particle Drift
100%
Patterned Surface
100%
Corrugation
100%
Particle Motion
66%
Corrugated Surface
66%
Particulate Suspension
66%
Pressure Field
33%
Three-dimensional (3D)
33%
Perturbation Theory
33%
Hydrodynamic Interaction
33%
Physical Mechanism
33%
Suspended Particles
33%
Spherical Particles
33%
Surface Topography
33%
Dynamical Behavior
33%
Universal Characteristic
33%
Particle Transport
33%
Disturbed Flow
33%
Flow Effect
33%
Microfabrication
33%
Microfluidic Device
33%
Particle Trajectory
33%
Microfluidic Applications
33%
Surface Shape
33%
Hydrodynamic Coupling
33%
Surface Characteristics
33%
Transverse Anisotropy
33%
Rectangular Corrugation
33%
Optimal Focusing
33%
Optimal Mixing
33%
Helix Dynamics
33%
Optimal Sorting
33%
Optimal Particle
33%
Sinusoidal Corrugation
33%
Triangular Corrugations
33%
Material Science
Hydrodynamics
100%
Particle Motion
100%
Anisotropy
50%
Surface Property
50%
Microfabrication
50%
Particle Transport
50%
Surface Topography
50%